NSP4 Genes Research Articles

Development of a Multiplex RT–qPCR Method for the Identification and Lineage Typing of Porcine Reproductive and Respiratory Syndrome Virus

Porcine reproductive and respiratory syndrome virus (PRRSV) is the pathogen that causes porcine reproductive and respiratory syndrome (PRRS), leading to abortion of sows and the manifestation of respiratory diseases in piglets. PRRSV strains are categorized into two distinct genotypes: PRRSV–1 and PRRSV–2. PRRSV–2 can be further classified into several lineages, including sub–lineage 1.8 (NADC30–like), sub–lineage 1.5 (NADC34–like), lineage 8 (HP–PRRSV–like), lineage 5 (VR–2332–like), and lineage 3 (QYYZ–like), all of which are prevalent in China. In order to identify PRRSV–1 and PRRSV–2, two primer–probe combinations were designed, targeting the M gene. In order to further differentiate the five lineages of PRRSV–2, another five primer–probe combinations were designed, targeting the Nsp2 gene. A TaqMan–based multiplex RT–qPCR assay was subsequently developed, integrating the aforementioned seven sets into two primer pools. Following the optimization of primer concentration and annealing temperature, a comprehensive evaluation was conducted to assess the assay’s amplification efficiency, specificity, repeatability, and sensitivity. The developed multiplex RT–qPCR method exhibited excellent repeatability, with coefficients of variation (CVs) less than 2.12%. The detection limits for all seven targets were found to be less than 5 copies/μL. Ultimately, the method was utilized for the detection of a total of 1009 clinical samples, with a PRRSV–positive rate of 7.63% (77/1009). Specifically, the reference method was utilized to further confirm the status of the 77 PRRSV–positive samples and another 27 samples suspected of PRRSV infection. The sensitivity of the method was 97.40% (75/77), and the specificity was 96.30% (26/27), resulting in an overall coincidence rate of 97.12% (101/104). All the PRRSV–positive samples were typed as NADC30–like strains, and the accuracy of this typing was further confirmed by Sanger sequencing. In conclusion, A one–step multiplex RT–qPCR method was successfully constructed, evaluated, and applied to detect clinical samples. The assay provides an easy–to–operate, time–saving, and highly efficient way for the quick identification of PRRSV and simultaneous detection of five PRRSV–2 lineages prevalent in China. The method could offer guidance for PRRSV prevention and control measures.

Development and Validation of RAA-CRISPR/Cas12a-Based Assay for Detecting Porcine Rotavirus

Piglet diarrhea poses significant economic losses to the pig industry, posing a worldwide challenge that urgently needs to be addressed in pig breeding practices. Porcine rotavirus (PoRV) is an important viral diarrhea pathogen in piglets, with a high incidence rate and a tendency to cause growth retardation. To enhance the sensitivity and specificity of PoRV detection, we sequenced the NSP3 gene of G5 and G9 genotypes of rotavirus A (RVA), enabling simultaneous detection of the two serotypes. Subsequently, we developed a rapid PoRV detection method using a combination of recombinase-aided amplification (RAA) and CRISPR/Cas12a. In this method, Cas12a binds to RAA amplification products, guided by CRISPR-derived RNA (crRNA), which activates its cleavage activity and releases fluorescence by cutting FAM-BHQ-labeled single-stranded DNA (ssDNA). In the optimized reaction system, the recombinant plasmid PoRV can achieve a highly sensitive reaction within 30 min at 37 °C, with a detection limit as low as 2.43 copies/μL, which is ten times higher in sensitivity compared to the qPCR method. Results from specificity testing indicate that no cross-reactivity was observed between the RAA-CRISPR/Cas12a analysis of PoRV and other viral pathogens, including PoRV G3, PoRV G4, porcine epidemic diarrhea virus (PEDV), porcine epidemic diarrhea (PDCoV), and porcine reproductive and respiratory syndrome virus (PRRSV). In the clinical sample detection using the RAA-CRISPR/Cas12a method and qPCR, Cohen’s Kappa value reached as high as 0.952. Furthermore, this approach eliminates the need for large-scale instrumentation, offering a visual result under an ultraviolet lamp through fluorescence signal output.

Mutations in the main antigenic sites of VP7 and VP8* from G3P[8] rotavirus a strains circulating in Brazil may impact immune evasion to rotavirus vaccination.

In the post-rotavirus (RVA) vaccination era, uncommon and zoonotic strains have emerged as causative agents of acute gastroenteritis in humans, including the equine-like G3P[8] strains. First identified in 2013, this strain has quickly spread worldwide, reaching the position of the most prevalent genotype in many countries, including Brazil. Here, we report full genotype characterization and phylogenetic analysis of two equine-like G3P[8] strains detected in Goiás, a state in the Cerrado biome of the Brazilian Midwestern region, during the year of 2019. The strains were detected in different socioeconomic and demographic contexts: GO-MR from an asymptomatic adult living in a rural traditional community and GO-H5 from a symptomatic child from the state capital, with access to safe drinking water and essential sanitation services. These strains also displayed different backbone constellations considering the NSP2 gene segment (G3-P [8]-I2-R2-C2-M2-A2-N2-T2-E2-H2 for GO-MR and G3-P[8]-I2-R2-C2-M2-A2-N1-T2-E2-H2 for GO-H5). Furthermore, significant mutations in the main epitope sites of the VP7 and VP8* proteins of the detected strains, and other Brazilian G3P[8] viruses, were found with the comparison to RV1 and RV5 vaccine proteins, indicating a potential ability of these viruses to evade vaccine protection, which may contribute to their prevalence both nationally and globally. In summary, this study corroborates the genetic diversity of equine-like G3P[8] DS-1-like strains circulating worldwide, highlights the epidemiological importance of adults as reservoirs of RVA and shows the substantial differences between these emerging strains and the currently used anti-RVA vaccines, which may partially explain their predominance due to potential evasion of vaccine-induced protection.

Rapid production of recombinant rotaviruses by overexpression of NSP2 and NSP5 genes with modified nucleotide sequences.

Reverse genetics systems for rotaviruses (RV) facilitate the generation of genetically engineered RVs by transfection of 11 plasmids encoding 11 genomic viral RNA segments. In addition to viral genome expression, overexpression of NSP2 and NSP5 has been used to increase the rescue efficiency of recombinant RVs. Here, we showed that the overexpression of nucleotide sequence-modified NSP2 and NSP5 enabled the rapid and efficient production of recombinant RVs. Using improved reverse genetics, we established a reverse genetics system for human and bovine RV clinical isolates, as well as laboratory strains of bovine RV (NCDV and UK) and porcine RV (Gottfried). In addition, we rescued low-replicating recombinant RVs carrying a mutant NSP4 lacking the double-layered particle-binding domain, which was deficient in the efficient production of mature virions. These advancements in reverse genetics enabled the generation of molecular clones of RV clinical isolates and recombinant RVs harboring critical amino acid mutations, offering a versatile platform for investigating RV biology and pathogenesis.IMPORTANCERecombinant rotavirus (RV) synthesis via reverse genetics relies on both the viral propagation capacity and the efficiency of the experimental system. Since the establishment of our reverse genetics system, several enhancements have been implemented to augment the rescue efficiency. Nevertheless, challenges persist in generating RV clinical strains and recombinant viruses with low replication capacities. Notably, this improved reverse genetics system successfully facilitated the establishment of molecular clones of human and bovine RV clinical isolates. Fecal samples from patients with RV typically harbor quasi-species or, occasionally, multiple genotypes of RV. In the present study, we performed the genetic sequencing of clinical viral strains during the early propagation stages in cultured cells. Subsequently, infectious viruses were synthesized, allowing the characterization of circulating viruses in nature. This approach provides valuable insights into the genetic diversity and dynamics of RV populations and contributes to a more comprehensive understanding of viral pathogenesis and evolution.

Emergence of non-classical genotype constellations of G9P[8] rotavirus strains in diarrheic children in Sabah, Malaysia

G9P[8] has been the predominant rotavirus A (RVA) genotype in Malaysia since the 2000s. However, the overall genetic makeup and evolution of Malaysian G9P[8] strains are still unknown. Therefore, this study aimed to evaluate and characterize the complete genomes of three G9P[8] RVA strains isolated from diarrheic children under five years old in Sabah. Contrary to the classical Wa-like constellation, these strains contained a DS-1-like genotype. Two strains, namely L202 and L234, were genotype G9-P[8]-I1-R1-C1-M1-A1-N1-T1-E2-H1, while one (KN102) was genotype G9-P[8]-I1-R1-C1-M1-A2-N1-T1-E1-H1. Phylogenetic analysis revealed that the NSP4 genes of L202 and L234 strains were closer to that of G9P[8]-E2 strains from Japan, suggesting they might share a common ancestor. The findings from this study provide new insights into the genetic characteristics of circulating G9P[8] strains in Sabah, which are important for rotavirus surveillance and potential vaccine development in the region.

Development of a Quadruplex RT-qPCR for the Detection of Feline Kobuvirus, Feline Astrovirus, Feline Bufavirus, and Feline Rotavirus

Feline kobuvirus (FeKoV), feline astrovirus (FeAstV), feline bufavirus (FeBuV), and feline rotavirus (FRV) are important pathogens for gastroenteritis, which is characterized by vomiting, diarrhea, and dehydration. Four pairs of primers and probes were designed to target the FeKoV VP1, FeAstV ORF2, FeBuV VP2, and FRV NSP4 genes, and a quadruplex real-time quantitative RT-PCR (RT-qPCR) assay capable of the simultaneous detection of four feline enteroviruses was developed after optimization of reaction conditions. The established quadruplex RT-qPCR assay showed high specificity, sensitivity, and reproducibility. The assay could detect and discriminate FeKoV, FeAstV, FeBuV, and FRV, but not other feline-related pathogens. The limits of detection (LODs) of FeKoV, FeAstV, FeBuV, and FRV were 109.761, 115.834, 125.481, and 113.875 copies/reaction, respectively. The intra- and inter-assay coefficients of variation (CV) were 0.15–1.61% and 0.15–1.59%, respectively. In all, 1869 clinical samples from Guangxi province in Southern China were tested using the developed assay, and the positivity rates of FeKoV, FeAstV, FeBuV, and FRV were 1.93%, 9.36%, 0.32%, and 0.75%, respectively. These samples were also tested using reference assays, and the coincidence rates of the results between the developed and reference methods were 99.63% (FeKoV), 98.72% (FeAstV), 100% (FeBuV), and 100% (FRV), respectively. The results indicated that the developed assay could provide a new detection method for these four viruses associated with feline gastroenteritis.

A chimeric strain of porcine reproductive and respiratory syndrome virus 2 derived from HP-PRRSV and NADC30-like PRRSV confers cross-protection against both strains

Porcine reproductive and respiratory syndrome (PRRS) is one of the most significant swine viral infectious diseases worldwide. Vaccination is a key strategy for the control and prevention of PRRS. At present, the NADC30-like PRRSV strain has become the predominant epidemic strain in China, superseding the HP-PRRSV strain. The existing commercial vaccines offer substantial protection against HP-PRRSV, but their efficacy against NADC30-like PRRSV is limited. The development of a novel vaccine that can provide valuable cross-protection against both NADC30-like PRRSV and HP-PRRSV is highly important. In this study, an infectious clone of a commercial MLV vaccine strain, GD (HP-PRRSV), was first generated (named rGD). A recombinant chimeric PRRSV strain, rGD-SX-5U2, was subsequently constructed by using rGD as a backbone and embedding several dominant immune genes, including the NSP2, ORF5, ORF6, and ORF7 genes, from an NADC30-like PRRSV isolate. In vitro experiments demonstrated that chimeric PRRSV rGD-SX-5U2 exhibited high tropism for MARC-145 cells, which is of paramount importance in the production of PRRSV vaccines. Moreover, subsequent in vivo inoculation and challenge experiments demonstrated that rGD-SX-5U2 confers cross-protection against both HP-PRRSV and NADC30-like PRRSV, including an improvement in ADG levels and a reduction in viremia and lung tissue lesions. In conclusion, our research demonstrated that the chimeric PRRSV strain rGD-SX-5U2 is a novel approach that can provide broad-spectrum protection against both HP-PRRSV and NADC30-like PRRSV. This may be a significant improvement over previous MLV vaccinations.

Identification and genotyping of Chikungunya virus using reverse transcription polymerase chain reaction and restriction fragment length polymorphism methods

INTRODUCTION. Chikungunya virus (CHIKV) genotyping involves sequencing fractions of genes encoding E1, E2, and nsP1 proteins or the entire genome of the virus. Available reagent kits or polymerase chain reaction protocols cannot be used for CHIKV genotyping, and nucleic acid sequencing requires expensive equipment and materials, which are not always available. Therefore, it seems promising to use a simpler and more cost-effective restriction fragment length polymorphism (RFLP) method, which has not previously been used for CHIKV genotyping.AIM. This study aimed to investigate the possibility of using reverse transcription polymerase chain reaction (RT-PCR) and RFLP for CHIKV identification and genotyping.MATERIALS AND METHODS. The experimental study used RNA from CHIKV strains of four genotypes, including the Asian, West African (WAf), and East/Central/South African (ECSA) genotypes, and the Indian Ocean Lineage of the ECSA genotype (ECSA-IOL). The study used RT-PCR followed by DNA restriction and restriction fragment length analysis.RESULTS. The nsP2 gene fragment of 648 bp in length (positions 3806 to 4453) contains recognition sites for the restriction endonucleases PspEI, PvuII, and DraI. The presence or absence of these sites generates a different combination specific to each of the four CHIKV genotypes. The authors designed primers for amplification of the selected gene region and performed RTPCR and RFLP.CONCLUSIONS. The RFLP method can be used for rapid CHIKV identification and genotyping. The method provides results within a few hours and does not require high-tech equipment.

Molecular genetic methods for quality control of inactivated vaccines using a Chikungunya virus model: vaccine strain identification and completeness of virus inactivation

INTRODUCTION. The completeness of virus inactivation and the identity of the vaccine strain are essential parameters for the safety and quality of inactivated virus vaccines, which should be controlled during vaccine development and production. Currently, the most promising quality control methods for inactivated virus vaccines are molecular genetic methods, which provide rapid results with high sensitivity and specificity.AIM. The aim of this study was the development of a real-time quantitative polymerase chain reaction (qPCR) method and an integrated cell culture real-time quantitative polymerase chain reaction (ICC-qPCR) method to assess the completeness of virus inactivation, as well as a reverse-transcription polymerase chain reaction assay coupled with restriction fragment length polymorphism analysis (RT-PCR-RFLP) to confirm the identity of the vaccine virus strain.MATERIALS AND METHODS. This study used RNA of CHIKV genotypes (three strains of each of the four CHIKV genotypes, including Asian, West African (WAf), and East/Central/South African (ECSA) genotypes, and the Indian Ocean Lineage of the ECSA genotype (ECSA-IOL), which were identified by sequencing prior to analysis). Additionally, the study used the Nika21 CHIKV strain (ECSA genotype), the Nika21 CHIKV strain inactivated with β-propiolactone, and the Nika21 CHIKV strain antigen adsorbed on aluminium hydroxide. The methods used included real-time qPCR, RT-PCR-RFLP, and virus neutralisation.RESULTS. The study identified a 218 bp fragment of the nsP1 gene (positions 789 to 1006) with restriction endonuclease recognition sites. These sites were present or absent in combinations specific to each of the four CHIKV genotypes. The authors selected primers for amplification of the specified gene region and tested the conditions for real-time qPCR and RT-PCR-RFLP. The study demonstrated the possibility of using the ICC-qPCR method to confirm the completeness of virus inactivation and the RT-PCR-RFLP method to identify the vaccine strain.CONCLUSIONS. The study showed the advantages of using the ICC-qPCR method to confirm the completeness of antigen inactivation and the RT-PCR-RFLP method to identify the vaccine strain. These methods are more sensitive and faster than traditional culture methods. ICC-qPCR and RT-PCR-RFLP can be used at any stage of the production process for inactivated vaccines.

The impact of host microRNAs on the development of conserved mutations of SARS-CoV-2.

SARS-CoV-2, the virus responsible for the COVID-19 pandemic, has undergone various genetic alterations due to evolutionary pressures exerted by host cells, including intracellular antiviral mechanisms such as targeting by human microRNAs (miRNAs). This study investigates the impact of miRNAs hsa-miR-3132 and hsa-miR-4650 on the viral genome. Sequence alignment revealed conserved mutations in the binding sites of these miRNAs in adapted strains compared to the original Wuhan-Hu-1 strain, leading to their deletion. Despite modest expression of these miRNAs in SARS-CoV-2 target tissues, their efficacy against mutant strains is reduced due to the loss of binding sites. Structural analysis indicates that the mutant genome is more stable than the Wuhan-Hu-1 genome. Luciferase and virus titration assays demonstrate that hsa-miR-3132 and hsa-miR-4650 effectively target the Nsp3 gene in the Wuhan-Hu-1 strain but not in mutant strains lacking their binding sites. These findings suggest that the observed mutations help the virus evade selective pressure from human miRNAs, contributing to its adaptation.

Full genome sequence analysis of the predominant and uncommon G9P[4] rotavirus strains circulating in Tehran, Iran, 2021–2022: Evidence for inter and intra-genotype recombination

Group A rotaviruses (RVAs) are a major cause of acute gastroenteritis in children under 5 years of age worldwide. Herein, the genetic sequences of 11 RNA segments from three uncommon G9P[4] RVA strains found in the stool samples of children under 5 years of age in Iran were analyzed using next-generation sequencing (NGS) technology. The genomic constellations of these three uncommon G9P[4] strains indicated the presence of the double and quadruple reassortants of two G9P[4] strains, containing the VP7/NSP2 and VP7/VP2/NSP2/NSP4 genes on a DS-1-like genetic background, respectively. The genome of one strain indicated a Wa-like genetic backbone in a single-reassortant with the VP4 of the DS1-like human strains. With the exception of VP1, VP2, VP7, NSP2, NSP3, and NSP4 genes, which clustered with RVA of human origins belonging to cognate gene sequences of genogroup 1/2 genotypes/lineages, the remaining five genes (VP8/VP4, VP3, VP6, NSP1, NSP5) displayed direct evidence of recombination. It is presumed that the presence of uncommon G9P[4] strains in Iran is not linked to vaccination pressure, but rather to the high prevalence of RVA co-infection or the direct import of these uncommon RVA reassortants strains from other countries (especially those that have implemented RV vaccination).

Independent repeated mutations within the alphaviruses Ross River virus and Barmah Forest virus indicates convergent evolution and past positive selection in ancestral populations despite ongoing purifying selection.

Ross River virus (RRV) and Barmah Forest virus (BFV) are arthritogenic arthropod-borne viruses (arboviruses) that exhibit generalist host associations and share distributions in Australia and Papua New Guinea (PNG). Using stochastic mapping and discrete-trait phylogenetic analyses, we profiled the independent evolution of RRV and BFV signature mutations. Analysis of 186 RRV and 88 BFV genomes demonstrated their viral evolution trajectories have involved repeated selection of mutations, particularly in the nonstructural protein 1 (nsP1) and envelope 3 (E3) genes suggesting convergent evolution. Convergent mutations in the nsP1 genes of RRV (residues 248 and 441) and BFV (residues 297 and 447) may be involved with catalytic enzyme mechanisms and host membrane interactions during viral RNA replication and capping. Convergent E3 mutations (RRV site 59 and BFV site 57) may be associated with enzymatic furin activity and cleavage of E3 from protein precursors assisting viral maturation and infectivity. Given their requirement to replicate in disparate insect and vertebrate hosts, convergent evolution in RRV and BFV may represent a dynamic link between their requirement to selectively 'fine-tune' intracellular host interactions and viral replicative enzymatic processes. Despite evidence of evolutionary convergence, selection pressure analyses did not reveal any RRV or BFV amino acid sites under strong positive selection and only weak positive selection for nonstructural protein sites. These findings may indicate that their alphavirus ancestors were subject to positive selection events which predisposed ongoing pervasive convergent evolution, and this largely supports continued purifying selection in RRV and BFV populations during their replication in mosquito and vertebrate hosts.

Sulforaphane's Nuclear Factor Erythroid 2-Related Factor 2 (Nrf2)-Dependent and -Independent Mechanism of Anti-SARS-CoV-2 Activity.

It is well established that Nrf2 plays a crucial role in anti-oxidant and anti-inflammatory functions. However, its antiviral capabilities remain less explored. Despite this, several Nrf2 activators have demonstrated anti-SARS-CoV-2 properties, though the mechanisms behind these effects are not fully understood. In this study, using two mouse models of SARS-CoV-2 infection, we observed that the absence of Nrf2 significantly increased viral load and altered inflammatory responses. Additionally, we evaluated five Nrf2 modulators. Notably, epigallocatechin gallate (EGCG), sulforaphane (SFN), and dimethyl fumarate (DMF) exhibited significant antiviral effects, with SFN being the most effective. SFN did not impact viral entry but appeared to inhibit the main protease (MPro) of SARS-CoV-2, encoded by the Nsp5 gene, as indicated by two protease inhibition assays. Moreover, using two Nrf2 knockout cell lines, we confirmed that SFN's antiviral activity occurs independently of Nrf2 activation in vitro. Paradoxically, in vivo tests using the MA30 model showed that SFN's antiviral function was completely lost in Nrf2 knockout mice. Thus, although SFN and potentially other Nrf2 modulators can inhibit SARS-CoV-2 independently of Nrf2 activation in cell models, their Nrf2-dependent activities might be crucial for antiviral defense under physiological conditions.

Low Prevalence of Nirmatrelvir-Ritonavir Resistance-Associated Mutations in SARS-CoV-2 Lineages From Botswana.

We evaluated naturally occurring nirmatrelvir-ritonavir (NTV/r) resistance-associated mutations (RAMs) among severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) strains from Botswana, a country with no NTV/r use to date, in order to recommend the usage of the agent for high-risk patients with coronavirus disease 2019 (COVID-19). We conducted a retrospective analysis using 5254 complete SARS-CoV-2 sequences from Botswana (September 2020-September 2023). We evaluated the mutational landscape of SARS-CoV-2 3-Chymotrypsin-like protease (3CLpro) relative to the highlighted list of RAMs granted Food and Drug Administration Emergency Use Authorization in 2023. The sequenced 5254 samples included Beta variants of concerns (VOCs; n = 323), Delta VOCs (n = 1314), and Omicron VOCs (n = 3354). Overall, 77.8% of the sequences exhibited at least 1 polymorphism within 76/306 amino acid positions in the nsp5 gene. NTV/rRAMs were identified in 34/5254 (0.65%; 95% CI, 0.43%-0.87%) and occurred at 5 distinct positions. Among the NTV/r RAMS detected, A191V was the most prevalent (24/34; 70.6%). Notably, T21I mutation had a prevalence of 20.6% (7/34) and coexisted with either K90R (n = 3) polymorphism in Beta sequences with RAMs or P132H (n = 3) polymorphism for Omicron sequences with RAMs. Other NTV/r RAMs detected included P108S, with a prevalence of 5.88% (2/34), and L50F, with a prevalence of 2.94% (1/34). NTV/r RAMs were significantly higher (P < .001) in Delta (24/35) compared with Beta (4/34) and Omicron (6/34) sequences. The frequency of NTV/r RAMs in Botswana was low. Higher rates were observed in Delta VOCs compared to Omicron and Beta VOCs. As NTV/r use expands globally, continuous surveillance for drug-resistant variants is essential, given the RAMs identified in our study.

The Stop Codon after the nsp3 Gene of Ross River Virus (RRV) Is Not Essential for Virus Replication in Three Cell Lines Tested, but RRV Replication Is Attenuated in HEK 293T Cells.

A recombinant Ross River virus (RRV) that contains the fluorescent protein mCherry fused to the non-structural protein 3 (nsP3) was constructed, which allowed real-time imaging of viral replication. RRV-mCherry contained either the natural opal stop codon after the nsP3 gene or was constructed without a stop codon. The mCherry fusion protein did not interfere with the viral life cycle and deletion of the stop codon did not change the replication capacity of RRV-mCherry. Comparison of RRV-mCherry and chikungunya virus-mCherry infections, however, showed a cell type-dependent delay in RRV-mCherry replication in HEK 293T cells. This delay was not caused by differences in cell entry, but rather by an impeded nsP expression caused by the RRV inhibitor ZAP (zinc finger CCCH-Type, antiviral 1). The data indicate that viral replication of alphaviruses is cell-type dependent, and might be unique for each alphavirus.

Evolution of DS-1-like G8P[8] rotavirus A strains from Vietnamese children with acute gastroenteritis (2014-21): Adaptation and loss of animal rotavirus-derived genes during human-to-human spread.

Animal rotaviruses A (RVAs) are considered the source of emerging, novel RVA strains that have the potential to cause global spread in humans. A case in point was the emergence of G8 bovine RVA consisting of the P[8] VP4 gene and the DS-1-like backbone genes that appeared to have jumped into humans recently. However, it was not well documented what evolutionary changes occurred on the animal RVA-derived genes during circulation in humans. Rotavirus surveillance in Vietnam found that DS-1-like G8P[8] strains emerged in 2014, circulated in two prevalent waves, and disappeared in 2021. This surveillance provided us with a unique opportunity to investigate the whole process of evolutionary changes, which occurred in an animal RVA that had jumped the host species barrier. Of the 843 G8P[8] samples collected from children with acute diarrhoea in Vietnam between 2014 and 2021, fifty-eight strains were selected based on their distinctive electropherotypes of the genomic RNA identified using polyacrylamide gel electrophoresis. Whole-genome sequence analysis of those fifty-eight strains showed that the strains dominant during the first wave of prevalence (2014-17) carried animal RVA-derived VP1, NSP2, and NSP4 genes. However, the strains from the second wave of prevalence (2018-21) lost these genes, which were replaced with cognate human RVA-derived genes, thus creating strain with G8P[8] on a fully DS-1-like human RVA gene backbone. The G8 VP7 and P[8] VP4 genes underwent some point mutations but the phylogenetic lineages to which they belonged remained unchanged. We, therefore, propose a hypothesis regarding the tendency for the animal RVA-derived genes to be expelled from the backbone genes of the progeny strains after crossing the host species barrier. This study underlines the importance of long-term surveillance of circulating wild-type strains in order to better understand the adaptation process and the fate of newly emerging, animal-derived RVA among the human population. Further studies are warranted to disclose the molecular mechanisms by which spillover animal RVAs become readily transmissible among humans, and the roles played by the expulsion of animal-derived genes and herd immunity formed in the local population.

Emergence of a Novel G4P[6] Porcine Rotavirus with Unique Sequence Duplication in NSP5 Gene in China.

Rotavirus is a major causative agent of diarrhoea in children, infants, and young animals around the world. The associated zoonotic risk necessitates the serious consideration of the complete genetic information of rotavirus. A segmented genome makes rotavirus prone to rearrangement and the formation of a new viral strain. Monitoring the molecular epidemiology of rotavirus is essential for its prevention and control. The quantitative RT-PCR targeting the NSP5 gene was used to detect rotavirus group A (RVA) in pig faecal samples, and two pairs of universal primers and protocols were used for amplifying the G and P genotype. The genotyping and phylogenetic analysis of 11 genes were performed by RT-PCR and a basic bioinformatics method. A unique G4P[6] rotavirus strain, designated S2CF (RVA/Pig-tc/CHN/S2CF/2023/G4P[6]), was identified in one faecal sample from a piglet with severe diarrhoea in Guangdong, China. Whole genome sequencing and analysis suggested that the 11 segments of the S2CF strain showed a unique Wa-like genotype constellation and a typical porcine RVA genomic configuration of G4-P[6]-I1-R1-C1-M1-A8-N1-T1-E1-H1. Notably, 4 of the 11 gene segments (VP4, VP6, VP2, and NSP5) clustered consistently with human-like RVAs, suggesting independent human-to-porcine interspecies transmission. Moreover, a unique 344-nt duplicated sequence was identified for the first time in the untranslated region of NSP5. This study further reveals the genetic diversity and potential inter-species transmission of porcine rotavirus.

NSP4 promotes replication of porcine reproductive and respiratory syndrome virus-2

Porcine reproductive and respiratory syndrome (PRRS) is one of the most detrimental contagious swine ailments worldwide. Currently, no effective drugs are available for its treatment. Targeting the structural and non-structural proteins (NSP) of the type 2 PRRS virus (PRRSV-2) with small interfering RNA (siRNA) is an effective approach to inhibit PRRSV replication. NSP4, which is highly conserved and possesses 3 C-like serine protease activity (3CLSP), can cleave PRRSV self-proteins, thereby contributing to viral replication. To investigate the mechanism by which NSP4 regulates PRRSV-2 replication and screen for effective siRNA inhibitors of PRRSV-2 replication, the recombinant plasmid pEGFP-C1-NSP4 was constructed, and a control siRNA pair and two siRNA pairs targeting the PRRSV-2 NSP4 gene (shRNA-ctr, shRNA-150, and shRNA-536) were synthesized and cloned into the pSilencer4.1-CMV vector. After 24 h of incubation, Marc-145 cells were transfected with recombinant plasmids, and subsequently infected with different PRRSV-2 (XH-GD, ZQ-GD, GDr180, and JXA1-R). Subsequently, the effects of NSP4 overexpression, shRNA on PRRSV-2 replication were evaluated by assessing cytopathic effects (CPE), TCID50, quantitative real-time PCR (qPCR), immunofluorescence assays (IFA), and Western blotting. The data from these CPE, TCID50, qPCR, and IFA experiments revealed that NSP4 overexpression significantly enhanced PRRSV-2 replication and shRNA targeting NSP4 can inhibit PRRSV-2 replication in Marc-145 cells, indicating that shRNA could serve as candidate molecules for fundamental research on PRRSV-2.

Molecular characterization of human astrovirus infection in children under 5 years of age with acute gastroenteritis in Tehran, Iran, 2021-2022: co-infection with rotavirus.

Human astroviruses (HAstVs) are considered important causative pathogens of acute gastroenteritis (AGE) in children under 5 years of age worldwide, along with group A rotavirus (RVA), norovirus (NoV), and enteric adenovirus (EAdV). The present study was aimed to both detect HAstV and its co-infections and investigate genetic analysis of circulating HAstV and co-infected virus in hospitalized children under 5 years of age with AGE in Iran. Accordingly, a sum of 200 stool specimens were screened by PCR for HAstV during 2021-2022. The HAstV was found in 0.5% of 200 specimens (n = 1) while was co-infected with RVA. The genetic and phylogenetic analysis indicated HAstV1 genotype, which clustered with viruses from lineage 1b, which has not been previously reported in Iran. The detected RVA strain belonged to G1 lineage II/P[8]-lineage III, which has been reported previously in Iran as the most common strain. The further genetic analysis of RVA VP6 and NSP4 demonstrated an atypical genotype pattern G1P[8]-I1-E2, as a mono-reassortant of a Wa-like genogroup, which appeared to be reassorted with the NSP4 gene of E2 genotype of the G2P[4] DS-1 genogroup. Although the clinical outcomes of the AGE-causing viruses co-infection is not yet entirely clear, it seems that future studies will be helpful to merge clinical and epidemiological data of co-infecting viruses for a more accurate medical and clinical relevance in symptomatic children.

Evaluation of different genomic regions of rotavirus B and rotavirus C for development of real-time RT‒PCR assays

BackgroundThe causative agents of diarrhea, rotavirus B (RVB) and rotavirus C (RVC) are common in adults and patients of all age groups, respectively. Due to the Rotavirus A (RVA) vaccination program, a significant decrease in the number of gastroenteritis cases has been observed globally. The replacement of RVA infections with RVB, RVC, or other related serogroups is suspected due to the possibility of reducing natural selective constraints due to RVA infections. The data available on RVB and RVC incidence are scant due to the lack of cheap and rapid commercial diagnostic assays and the focus on RVA infections. The present study aimed to develop real-time RT‒PCR assays using the data from all genomic RNA segments of human RVB and RVC strains available in the Gene Bank.ResultsAmong the 11 gene segments, NSP3 and NSP5 of RVB and the VP6 gene of RVC were found to be suitable for real-time RT‒PCR (qRT‒PCR) assays. Fecal specimens collected from diarrheal patients were tested simultaneously for the presence of RVB (n = 192) and RVC (n = 188) using the respective conventional RT‒PCR and newly developed qRT‒PCR assays. All RVB- and RVC-positive specimens were reactive in their respective qRT‒PCR assays and had Ct values ranging between 23.69 and 41.97 and 11.49 and 36.05, respectively. All known positive and negative specimens for other viral agents were nonreactive, and comparative analysis showed 100% concordance with conventional RT‒PCR assays.ConclusionsThe suitability of the NSP5 gene of RVB and the VP6 gene of RVC was verified via qRT‒PCR assays, which showed 100% sensitivity and specificity. The rapid qRT‒PCR assays developed will be useful diagnostic tools, especially during diarrheal outbreaks for testing non-RVA rotaviral agents and reducing the unnecessary use of antibiotics.